Card edge connector having means for applying inward transverse force on printed wiring boards

ABSTRACT

Disclosed is a card edge connector which has a pivoting latching mechanism that has a pair of parallel fingers that direct inward transverse forces on the opposed sides of the printed wiring board to secure it in the connector. The connector also includes a plate on each of the contact elements which prevents overstressing of the arcuate element of the contact. The plate also includes a longitudinal projection and an opposed longitudinal recess so that the contact elements resist axial forces.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is related to application Ser. No.0/518 994 entitled"Card Edge Connector Having Means for Preventing Overstress of ContactElements" and application Ser. No. 08/526797 entitled "Connector".

BACKGROUND OF INVENTION

1. Field of the Invention

The present invention relates to electrical connectors and moreparticularly to card edge connectors.

2. Brief Description of the Prior Developments

Various card edge connectors are known in the art in which the frontedge of a printed wiring board is inserted in a longitudinal groove ofthe insulated housing. Adjacent that groove there are a plurality ofcontacts with arcuate conductive sections arranged in side by siderelation adjacent the groove so that conductive pads on the printedwiring board contact the arcuate sections of the contacts as the boardis inserted into the groove. Such edge card connectors may employlatches for locking the printed wiring board into the connector.

In such arrangements the printed wiring board must be firmly affixed inthe connector. A continuing need, therefore, exists for improved latchesfor firmly and efficiently affixing the wiring board in the connector.

Another problem which may occur with such devices is that the contactelements may be overstressed as the printed wiring board is insertedinto the groove, resulting in a loss of contact normal force. A need,therefore, exists for a means of preventing such overstressing of thecontact elements.

Another problem involves the fact that a large number of side by sidecontacts must be inserted into the housing and securely retainedtherein, in a manner that does not impart undue stress on the housingand yet resists forces that would tend to push the contacts out of thehousing. A need, therefore, exists for means of providing optimuminsertion and retention of the contacts in the housing.

SUMMARY OF THE INVENTION

In the card edge connector of the present invention, latching mechanismsare provided on each side of the insulative housing to secure theprinted wiring board in position. These latching mechanisms arepivotally connected to upstanding sections of the insulative housing andpivot in an arc to engage upper tabs on upstanding end sections of theinsulative housing. These vertical tabs are positioned on opposite sidesof the printed wiring board so that, as the latching mechanism ispivoted into position, parallel fingers on the latching mechanism pressthe upwardly extending tabs on the vertical section of the insulativehousing toward each other to provide an inwardly directed transverseforce on the printed wiring board to secure it in position.

In the card connector of the present invention, there is also a verticalplate which extends upwardly from the base section of each of thecontacts. This plate has an upper surface which is opposed to theterminal end of the arcuate section of the contact and preventsoverstress of that arcuate section as the printed wiring board isengaged with the contact.

On the plate section of each of the contacts there is also alongitudinal projection which has an opposed longitudinal recess. Eachsuch projection engages a groove in the housing so that a longitudinalguiding function is provided during initial insertion of the contacts.The projection cooperates with the housing to retain the contact in thehousing after final insertion.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described with reference to theaccompanying drawings in which:

FIG. 1 is a side elevational view of a preferred embodiment of the edgeconnector of the present invention;

FIG. 2 is a top plan view of the edge connector shown in FIG. 1;

FIG. 3 is an end view of the edge connector shown in FIG. 1;

FIG. 3A is an enlarged view of the bottom portion of the edge connectorcircled in FIG. 2.

FIG. 3B is a sectional view through line V--V of FIG. 3a

FIG. 4 is a cross sectional view through line IV--IV in FIG. 2;

FIG. 5 is a perspective view of the edge connector shown in FIG. 1 inwhich one latching mechanism has been removed to better display otheraspects of the edge connector;

FIG. 6 is a side elevational view of the latching mechanism used in theedge connector of the present invention;

FIG. 7 is a front view of the latching mechanism shown in FIG. 6;

FIG. 8 is a rear view of the latching mechanism shown in FIG. 6;

FIG. 9 is a top plan row of the latching mechanism shown in FIG. 6;

FIG. 10 is a bottom view of the latching mechanism shown in FIG. 6;

FIG. 11 is a detailed view of the area within circle XI in FIG. 6;

FIG. 12 is a perspective view of the latching mechanism shown in FIG. 6;

FIG. 13 is a side elevational view of one of the contact elements shownin FIG. 1;

FIG. 14 is an end view of the contact elements shown in FIG. 13;

FIG. 15 is a perspective view of the contact elements shown in FIG. 13;

FIG. 16 is a side elevational view of a preferred embodiment of theprinted wiring board edge connector of the present invention;

FIG. 17 is a top plan view of the edge connector shown in FIG. 16;

FIG. 18 is an end view of the edge connector shown in FIG. 16;

FIG. 19 is a cross sectional view through XIX--XIX in FIG. 17;

FIG. 20 is a side elevational view of a contact element used in the edge

connector shown in FIG. 16; and

FIG. 21 is an end view of the contact element shown in FIG. 20.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to the FIGS. 1-7, the edge connector includes a moldedinsulative housing 10 which has a first end 12 and a second end 14 whichare connected by a groove 15 in its topside 16. This housing alsoincludes a bottom side 18 and a first lateral side 20 and a secondlateral side 22. A printed wiring board is shown in phantom linesgenerally at numeral 23. This board has a front edge 24 which engagesthe groove in the housing and an opposed top edge 25 and a first sideedge 26 and a second side edge 27. The front edge is supported on boardrest 28. The printed wiring board has conductive pads (not shown)disposed along each side of edge 24. Rows of contacts 29 and 30 (FIG. 2)are positioned on opposite sides of the groove 15. Each contact orterminal 29 or 30 forms an electrical connection with a correspondingone of the conducting pads. Extending from the bottom side of thehousing are leads as at 32 and 34 and non-conductive locating pins as at36 and 38 both of which engage a mother board (not shown). The housingalso includes a first upstanding member 40 which has a groove 41 alignedwith and substantially the same width as groove 15 and a secondupstanding member 42 which also has a groove 43 aligned with andsubstantially the same width as groove 15. Tabs 44 and 46 extend frommembers 40 and 42 respectively. The grooves 41 and 43 also extendvertically through these tabs, The housing also includes stand-offs asat 48 and 50 which bear against the mother board when the housing isengaged with the mother board. Finally, the edge connector includes afirst latching member shown generally at numeral 52 and a secondlatching member shown generally at 54.

Referring to FIG. 5, each tab 44, 46 has a raised rib, such as ribs 46A,46B extending adjacent the front edge of the tab. The upstanding members40 and 42 each include a split web 45 having portions 45A and 45B. Theweb is split so that the opposed portions of each of upstanding members40 and 42 can move toward and away from each other. On the interiorsurfaces of the upstanding members, 40 and 42, adjacent the webs 45 area pair of V-shaped grooves 47 that am sized to receive the projections66, 68 of the latching mechanisms.

Referring to FIG. 6-11, each of these latching mechanisms includes anupper shank 56 and a lower ejectment hook 58. On the upper shank thereare lateral pivot projections 60 and 62 by means of which the latchingmechanism is fixed to apertures in the insulative housing. The latchingmechanisms also include a longitudinal rib 64, lateral engagementprojections 66 and 68, fingers 70 and 72 and lateral tabs 74 and 76.Each of the latching members pivots on projections 60 or 62 from aposition in which it is engaged with printed wiring boards to a rearwardangular position in which it is disengaged from the board. With thelatches in their rearward disengaged position, the printed wiring boardis inserted in the housing so that its front edge engages groove 15 andits side edges respectively engage grooves 41 and 43 in the verticalmembers 40, 42. Because the web 45 is split, the grooves 41 and 43 areslightly wider than the thickness of the board and the board easilyslips into the connector. As the printed wiring board is pushed intoslot 15, the edge 24 of the board engages the ejectment hook 58 of eachlatch causing the latch to pivot on projections 60, 62. As the latchpivots, fingers 70 and 72 slide over tabs 44 and 46. The fingers 70 and72 engage the raised ribs 44A and 46A on the tabs 44, 46 and cam thesetabs inwardly so that the edges of grooves 41 and 43 are pressed againstand clamp against the opposed lateral sides of the printed wiring boardto thereby securely hold the printed wiring board in the connector. Asthe latch moves to the closed position, the projections 66 and 68 snapinto the grooves 47, so that each latch is locked in the closedposition. The latching mechanism also includes a head section showngenerally at numeral 78. In the locked position, the front nose 80 ofthe head section will engage a recess in the printed wiring board sothat the board is properly located and secured in position. The latchingmechanism will ordinarily be manipulated by means of the finger tab 82,to rotate the latch and eject the board from the connector.

Referring to FIGS. 13 and 14, each of the contact elements includes acantilevered contact arm including a vertical section 84, an arcuatesection 86 and a terminal end 88 on the arcuate section. The verticalsection extends from a base 90 and in the opposite direction from thevertical section there is a lead 92 extending from the base. Alsoextending laterally and vertically and from the base is a support plate94 for mounting the terminal in housing 10. Extending from a side of thesupport plate there is an elongated projection 96 preferably stampedfrom plate 94 and on the opposite side of the support plate from thisprojection there is a recess 98. In a position opposed to the terminalend of the arcuate section the support plate has a terminal end supportsurface 100 formed in an edge of plate 94. The purpose of this surfaceis to prevent overstressing of the arcuate section as the printed wiringboard is inserted into the groove of the insulated housing. The gapbetween surface 100 and the tip of terminal end 88 is dimensioned sothat, as the tip end is moved as a result of insertion of the board, thetip end will bump against surface 100 before there is any permanentdeformation of the contact arm. The outer edge 95 of the support platealso has a recessed surface 102 that has, at an upper edge, a retentionbarb 103 and, along the lower edge, a locating surface 106 As can beseen in FIG. 13, the barb 103 is positioned at a location along plate 94that is intermediate the longitudinal extent of projection 96.

Each of the contacts 29, 30 is received in one of a plurality ofterminal or contact recesses 107 in the housing of connector 10. Eachrecess 107 includes a groove 108 extending in one of the side walls ofthe recess. The width w of this groove (FIG. 3B) is slightly wider thanthe width t of the projection 96. Preferably, the dimension s, whichlocates the top of the projection 96, is such that when the contact isin its final position, the top portion of the projection 96, ispositioned at the top of the groove 108. The groove 108 extends from thebottom surface 18 toward top surface 16 and is substantially inalignment with the direction of insertion of board 23 into boardreceiving groove 15.

The projection 96 and groove 108 interact in the following manner. Whenthe contacts 29, 30 are loaded for insertion in housing 10, they can beplaced with the projection 96 in the groove 108. Because the groove isslightly wider than the projection, the projection slides in the grooveuntil the barb 103 engages the board rest 28. By appropriatedimensioning of the height h of the projection, the longitudinal outersurface of the projection bears lightly on the bottom surface of thegroove 108 to provide a relatively low transversely directed force tocause the opposed side of the plate 94 to bear against the side wall ofrecess 107 opposed to groove 108. As a result of the transverse force,sufficient axial retention force is generated to retain the terminal inthe housing prior to final assembly. After final assembly the combinedeffects of this retention force and the retention force generated bybarb 103, the contacts are held axially in the housing. This retentionis achieved without generating a high transverse force in the directionof the longitudinal axis of the housing, which can be cumulative alongthe row of contacts and result in warpage of the housing. Thecooperation between projection 96 and groove 108 also serves topreliminarily position and locate the contacts properly for finalinsertion. This is especially useful for hand insertion. When all thecontacts are so loaded, a final insertion step, such as one using an aircylinder, can be used to push all the contacts into final position ineach recess 107. In the final position the locating surface 106 ispositioned against step 28a in the board rest 28.

It should be noted that the hollow projection 96 can be viewed as asimply supported structure with its ends connected to plate 94. Theelongated projection imparts a limited transverse force, therebylimiting the tendency for the contacts to impart stress on the housingthat could cause warpage.

Referring to FIGS. 16-19 a second embodiment of the edge connectorincludes a molded insulated housing 210 which has a first end 212 and asecond end 214 which are connected by a groove 215 in its topside 216.This housing includes a first lateral side 220 and a second lateral side222. A right angled section 221 having a base side 218 extends below thehousing. A printed wiring board is shown in phantom lines generally atnumeral 223. This board has a front edge 224 which engages the groove inthe housing and an opposed top edge 225 and a first edge 226 and asecond edge 227. The front edge is supported on board rest 228. As isconventional, the printed wiring board has conductive pads which areconnected to contact elements as at 229 and 230 which are positioned onopposite sides of the groove. Extending from the base side at the rightangle section are leads as at 232 and 234 and non-conductive pins as at236 and 238 both of which engage a mother board. The housing alsoincludes the first vertical member 240 which has a groove 241 which is acontinuation of groove 215 and a second vertical member 242 which alsohas a groove 243 which is continuation of groove 215. Tabs 244 and 246which have a thinner thickness than the vertical members extendvertically upwardly, respectively, from vertical members. The grooves241 and 243 also extend vertically through these tabs. Finally the edgeconnector includes a first latching member shown generally at numeral252 and a second latching member shown generally at 254. These latchingmembers may be essentially identical to those shown above in FIGS. 6-11.

Referring to FIGS. 20 and 21, each of the contact elements comprises avertical section 284 an arcuate section 286 and a terminal end 288 onthe arcuate section. The vertical section extends from a base 290.Extending laterally from the base there is a lead 292. Extendingvertically from the base is a support plate 294. Extendinglongitudinally from this support plate there is a projection 296 and onthe opposite side of the support plate from this projection there is arecess 298. In a position opposed to the terminal end of the arcuatesection the support plate has a terminal end support surface 300. Thepurpose of this surface is to prevent overstressing of the arcuatesection as the printed wiring board is inserted into the groove of theinsulated housing. The support plate also has another recessed surface302.

It will be appreciated that a card edge connector has been describedwhich effectively, efficiently and economically secures the printedwiring board prevents overstressing the arcuate sections of the contactelement and prevents axial displacement and disengagement of the contactelements.

While the present invention has been described in connection with thepreferred embodiments of the various figures, it is to be understoodthat other similar embodiments may be used or modifications andadditions may be made to the described embodiment for performing thesame function of the present invention without deviating therefrom.Therefore, the present invention should not be limited to any singleembodiment, but rather construed in breadth and scope in accordance withthe recitation of the appended claims.

What is claimed is:
 1. An insertion and ejection card edge connectorassembly for a printed circuit board having opposed first and secondends, top and front edges and lateral sides comprising:(a) an elongatedlongitudinal housing having first and second opposed ends and lateralsides and a bottom side and a longitudinal board receiving grooveinterposed between said lateral sides such that the front edge of theprinted wiring board is receivable in said board receiving groove and atsaid first and second opposed ends said housing has first and secondupstanding members and each of said upstanding members has a verticalgroove having opposed edges and a split web having opposed portionsmoveable toward and away from each other and adjacent each of said websthere are tabs and each of said tabs has a front edge and a raised ribadjacent said front edge and the printed wiring board has opposedlateral sides and an inward transverse force is exerted normal to saidlateral sides to exert force on both of said opposed lateral sides ofthe printed wiring board; and (b) a first and a second latching meanseach of said latching means having an upper shank and a lower ejectmenthook and being attached to the housing at said first and second opposedends by lateral pivot projections so as to be pivotable in an arc andeach of said latching means has a pair of parallel transversely spacedresilient fingers on said upper shank for exerting the inward transverseforce on the printed wiring board whereby each of the resilient fingersoverlaps one of the tabs such that said resilient fingers engage theraised ribs on the tabs and cam said tabs inwardly so that the edges ofthe grooves press against the opposed lateral sides of the printedwiring board.
 2. The edge connector assembly of claim 1 wherein at leastone longitudinal row of electrical contact elements is positionedadjacent said board receiving groove and in which each of said contactelements has a first section which extends from adjacent the bottom sideand a generally arcuate second section which extends transversely fromthe first section to a terminal end means for supporting the terminalend of the arcuate second section of the contact element.
 3. The edgeconnector of claim 2 wherein the means for supporting the terminal endof the arcuate second section of at least one of the contact elements isa plate positioned in generally coplanar arrangement with said contactelement.
 4. The edge connector of claim 3 wherein said contact elementhas a base section which extends transversely from the first section anda pin which extends downwardly from said base section.
 5. The edgeconnector of claim 4 wherein the plate section extends upwardly fromsaid base section.
 6. The edge connector of claim 5 wherein the terminalend of the contact element extends generally radially inwardly from thearcuate section.
 7. The edge connector of claim 5 wherein the supportplate has a contact engagement surface which is generally normal to theterminal end of the contact.
 8. The edge connector of claim 1 wherein atleast one longitudinal row of electrical contact elements is positionedadjacent said card receiving row.
 9. The edge connector of claim 8wherein at least one contact element has a longitudinal projection. 10.The edge connector of claim 9 wherein said one contact element has alongitudinal recess and in opposed relation to the longitudinalprojection.
 11. The edge connector of claim 9 wherein each of saidcontact elements has a base section which extends transversely from thefirst section and a pin which extends downwardly from said base section.12. The edge connector of claim 11 wherein at least some of the contactelements have a plate section which extends upwardly from the basesection.
 13. The edge connector of claim 12 wherein projections andopposed recesses are formed on the plate section.